A receiver recovers local service data symbols from first Orthogonal Frequency Division Multiplexed (OFDM) symbols in the presence of second OFDM symbols, the second OFDM symbols carry national broadcast data symbols and modulated on to the sub-carriers of the second OFDM symbols using a first modulation scheme, and the first OFDM symbols carry the national broadcast data symbols and the local service data symbols from a local insertion pipe and modulated on to the sub-carriers of the first OFDM symbols using a second modulation scheme. The receiver comprises an OFDM detector which includes an equalizer for recovering local service modulated sub-carriers of the second modulation scheme by generating an estimate of a combined channel ([Hn(z)+Hl(z)]) via which the first and second OFDM symbols have passed using the pilot sub-carrier symbols of the first and second OFDM symbols; generating an estimate of national broadcast modulation symbols from the modulated data bearing sub-carriers of the first modulation scheme from the second OFDM symbols (Ŝ(z)); generating an estimate of a convolution of the combined channel and the national broadcast modulation symbols (Ŝ(z)[Hn(z)+Hl(z)]); generating an estimate of a component of the received base band signal representing the local service modulation symbols of the first OFDM symbol; generating an estimate of a channel via which the first OFDM symbols were received using the local pilot symbols (Ĥl(z)); and generating an estimate of local service data symbols from a combination of the estimate of the component of the received signal representing the modulation symbols carrying the local service data and the estimate of the channel via which the first OFDM symbols were received
Legal claims defining the scope of protection. Each claim is shown in both the original legal language and a plain English translation.
1. A base station for communicating data using Orthogonal Frequency Division Multiplexed (OFDM) symbols to a first receiver and a second receiver, comprising: modulation circuitry configured to modulate first and second input data symbols onto sub-carrier signals of OFDM symbols, which are intended for receipt by the first and second receivers, respectively, based on proximity of the first and second receivers to the base station, both the first and second input data symbols being modulated onto the sub-carrier signals of the OFDM symbols, the modulation being performed for both the first and second input data symbols using a common modulation scheme; and transmission circuitry configured to form a baseband signal including the OFDM symbols and to transmit the baseband signal, wherein the first input data symbols are encoded more robustly than the second input data symbols such that when the baseband signal including the OFDM symbols is received at the first receiver, the modulated second input data symbols in the OFDM symbols appear to the first receiver as noise, wherein the first receiver is farther away from the base station than the second receiver, wherein the common modulation scheme is an N-QAM modulation scheme, where N=2 to the (A+B)th power, A being a first value which is a number of bits that are used to select a constellation point in a modulation scheme used for modulating the first input data symbols, and B being a second value which is a number of bits that is used to select a constellation point in a modulation scheme used for modulating the second input data symbols, and wherein the modulation circuitry is configured to modulate data representing signaling data indicating when both of the first and the second input data symbols are modulated on the OFDM symbols.
A base station transmits data to nearby and distant receivers using OFDM. It modulates two sets of data (one for each receiver) onto the same sub-carriers using a single N-QAM modulation scheme (where N is determined by the number of bits used for each data set). Data for the distant receiver is encoded more robustly, so the nearby receiver's data looks like noise to it. The base station also broadcasts signaling data to indicate when both data sets are present on the OFDM symbols.
2. The base station according to claim 1 , wherein the order of the constellation A is different from the order of the constellation B.
The base station described in Claim 1 uses an N-QAM modulation scheme derived from two separate constellations to encode data for nearby and distant receivers. The order of the constellation used for the distant receiver (A) is different from the order of the constellation used for the nearby receiver (B).
3. The base station according to claim 1 , wherein the first and second data input symbols are modulated onto signals transmitted in a same frequency band, the signals being intended for receipt by the first and second receivers in the same frequency band.
The base station described in Claim 1 transmits data to both nearby and distant receivers using the same frequency band. The first and second data input symbols are modulated onto signals transmitted in this same frequency band, ensuring simultaneous transmission to both types of receivers without frequency division.
4. The base station according to claim 1 , wherein the base station includes pilot generation circuitry configured to insert pilots into one or more of the sub-carrier signals of the OFDM symbols.
The base station described in Claim 1 also includes a pilot signal generator. This generator inserts pilot signals into one or more sub-carriers of the OFDM symbols. These pilots can be used by the receivers for channel estimation and synchronization, improving reception quality for both near and far receivers.
5. The base station according to claim 1 , wherein the modulation circuitry is configured to map the first and second input data symbols to a constellation for the common modulation scheme, the first and second input data symbols being allocated to respective predetermined bit positions in the constellation.
The base station described in Claim 1 maps the data for the nearby and distant receivers to a single constellation used by the common modulation scheme (N-QAM). Each data stream is assigned to specific, predetermined bit positions within the constellation, allowing the receiver to separate the intended data from the other.
6. The base station according to claim 1 , wherein the base station further includes forward error correction encoder circuitry configured to forward error correction encode the first input data symbols and the second input data symbols differently relative to one another.
The base station described in Claim 1 also uses forward error correction (FEC) to encode the data for both nearby and distant receivers. However, it encodes them differently; for example, the data for the distant receiver is encoded with a stronger FEC scheme than the nearby receiver, providing more robustness.
7. The base station according to claim 1 , wherein the base station further includes interleaver circuitry configured to interleave the first input data symbols and the second input data symbols differently relative to one another.
The base station described in Claim 1 contains interleaver circuitry. The data for the nearby and distant receivers is interleaved differently, providing greater resilience to burst errors during transmission.
8. The base station according to claim 1 , wherein, regarding the more robust encoding, the first input data symbols, when represented in the baseband signal, have a signal-to-noise ratio greater than a signal-to-noise ratio of the second input data symbols when represented in the baseband signal.
The base station described in Claim 1 encodes the data intended for the distant receiver (the "more robust encoding") such that its signal-to-noise ratio (SNR) in the baseband signal is higher than the SNR of the data intended for the nearby receiver. This difference in SNR is a result of the encoding and power allocation.
9. A base station for communicating data using Orthogonal Frequency Division Multiplexed (OFDM) symbols to a first receiver and a second receiver, comprising: modulation circuitry configured to modulate first and second input data symbols onto sub-carrier signals of OFDM symbols, which are intended for receipt by the first and second receivers, respectively, based on proximity of the first and second receivers to the base station, both the first and second input data symbols being modulated onto the sub-carrier signals of the OFDM symbols, the modulation being performed for both the first and second input data symbols using a common modulation scheme; and transmission circuitry configured to form a baseband signal including the OFDM symbols and to transmit the baseband signal, wherein the first input data symbols are encoded more robustly than the second input data symbols such that when the baseband signal including the OFDM symbols is received at the first receiver, the modulated second input data symbols in the OFDM symbols appear to the first receiver as noise, wherein the first receiver is farther away from the base station than the second receiver, wherein the common modulation scheme is an N-QAM modulation scheme, where N=2 to the (A+B)th power, A being a first value which is a number of bits that are used to select a constellation point in a modulation scheme used for modulating the first input data symbols, and B being a second value which is a number of bits that is used to select a constellation point in a modulation scheme used for modulating the second input data symbols, and wherein the base station further comprises scheduler circuitry configured to receive control signals and, dependent on a control signal of the control signals, modulate only the first data symbol or only the second data symbol onto a corresponding one of the sub-carrier signals of OFDM symbols.
A base station transmits data to nearby and distant receivers using OFDM. It modulates two sets of data (one for each receiver) onto the same sub-carriers using a single N-QAM modulation scheme (where N is determined by the number of bits used for each data set). Data for the distant receiver is encoded more robustly, so the nearby receiver's data looks like noise to it. Additionally, scheduler circuitry allows for modulating ONLY the first data symbol or ONLY the second data symbol onto the corresponding sub-carrier signals of the OFDM symbols.
10. A method comprising: modulating, using circuitry, first and second input data symbols onto sub-carrier signals of OFDM symbols, which are intended for receipt by respective first and second receivers, based on proximity of the first and second receivers to a base station, both the first and second input data symbols being modulated onto the sub-carrier signals of the OFDM symbols, the modulation being performed for both the first and second input data symbols using a common modulation scheme; and forming, using the circuitry, a baseband signal including the OFDM symbols and transmitting the baseband signal, wherein the first input data symbols are encoded more robustly than the second input data symbols such that when the baseband signal including the OFDM symbols is received at the first receiver, the modulated second input data symbols in the OFDM symbols appear to the first receiver as noise, wherein the first receiver is farther away from the base station than the second receiver, wherein the common modulation scheme is an N-QAM modulation scheme, where N=2 to the (A+B)th power, A being a first value which is a number of bits that are used to select a constellation point in a modulation scheme used for modulating the first input data symbols, and B being a second value which is a number of bits that is used to select a constellation point in a modulation scheme used for modulating the second input data symbols, and the method further comprising modulating data representing signaling data indicating when both of the first and the second input data symbols are modulated on the OFDM symbols.
A method for transmitting data from a base station to nearby and distant receivers using OFDM involves modulating two sets of data (one for each receiver) onto the same sub-carriers using a single N-QAM modulation scheme (where N is determined by the number of bits used for each data set). The data for the distant receiver is encoded more robustly, so the nearby receiver's data looks like noise to it. The method also broadcasts signaling data to indicate when both data sets are present on the OFDM symbols.
11. The method according to claim 10 , wherein the order of the constellation A is different from the order of the constellation B.
The method described in Claim 10, which uses an N-QAM modulation scheme derived from two separate constellations to encode data for nearby and distant receivers, includes using a constellation for the distant receiver (A) with a different order than the constellation used for the nearby receiver (B).
12. The method according to claim 10 , wherein the first and second data input symbols are modulated onto signals transmitted in a same frequency band, the signals being intended for receipt by the first and second receivers in the same frequency band.
The method described in Claim 10 transmits data to both nearby and distant receivers using the same frequency band. The first and second data input symbols are modulated onto signals transmitted in this same frequency band, ensuring simultaneous transmission to both types of receivers without frequency division.
13. The method according to claim 10 , further comprising mapping the first and second input data symbols to a constellation for the common modulation scheme, the first and second input data symbols being allocated to respective predetermined bit positions in the constellation.
The method described in Claim 10 also maps the data for the nearby and distant receivers to a single constellation used by the common modulation scheme (N-QAM). Each data stream is assigned to specific, predetermined bit positions within the constellation, allowing the receiver to separate the intended data from the other.
14. The method according to claim 10 , wherein, regarding a more robust encoding, the first input data symbols, when represented in the baseband signal, have a signal-to-noise ratio greater than a signal-to-noise ratio of the second input data symbols when represented in the baseband signal.
The method described in Claim 10 encodes the data intended for the distant receiver (the "more robust encoding") such that its signal-to-noise ratio (SNR) in the baseband signal is higher than the SNR of the data intended for the nearby receiver.
15. A method comprising: modulating, using circuitry, first and second input data symbols onto sub-carrier signals of OFDM symbols, which are intended for receipt by respective first and second receivers, based on proximity of the first and second receivers to a base station, both the first and second input data symbols being modulated onto the sub-carrier signals of the OFDM symbols, the modulation being performed for both the first and second input data symbols using a common modulation scheme; and forming, using the circuitry, a baseband signal including the OFDM symbols and transmitting the baseband signal, wherein the first input data symbols are encoded more robustly than the second input data symbols such that when the baseband signal including the OFDM symbols is received at the first receiver, the modulated second input data symbols in the OFDM symbols appear to the first receiver as noise, wherein the first receiver is farther away from the base station than the second receiver, wherein the common modulation scheme is an N-QAM modulation scheme, where N=2 to the (A+B)th power, A being a first value which is a number of bits that are used to select a constellation point in a modulation scheme used for modulating the first input data symbols, and B being a second value which is a number of bits that is used to select a constellation point in a modulation scheme used for modulating the second input data symbols, and the method further comprising: receiving control signals; and dependent on a control signal of the control signals, modulating only the first data symbol or only the second data symbol onto a corresponding one of the sub-carrier signals of OFDM symbols.
A method for transmitting data from a base station to nearby and distant receivers using OFDM involves modulating two sets of data (one for each receiver) onto the same sub-carriers using a single N-QAM modulation scheme (where N is determined by the number of bits used for each data set). The data for the distant receiver is encoded more robustly, so the nearby receiver's data looks like noise to it. Additionally, the method includes receiving control signals and modulating ONLY the first data symbol or ONLY the second data symbol onto the corresponding sub-carrier signals of the OFDM symbols, depending on the control signal.
Cooperative Patent Classification codes for this invention. Click any code to explore related patents in that topic.
August 10, 2015
May 2, 2017
Browse 5M+ US patents with plain-English claim translations and AI-generated analysis.